Tailoring polarization singularities in degenerate bands through structural symmetry and magnetic field

物理 简并能级 引力奇点 极化(电化学) 磁场 奇点 圆极化 反射对称性 对称性破坏 镜像对称 量子力学 凝聚态物理 退化(生物学) 对称运算 对称(几何) 拓扑(电路) 消灭 Dirac(视频压缩格式) 场强 束缚态 领域(数学) 线极化 经典力学 圆对称性 局部对称性
作者
Zhao, Xingchen,Xiangke, Li,Yang, Shanqi,zhang, chiyu,Zhang, Kun,Kong, Weijin
出处
期刊: [Figshare (United Kingdom)]
标识
DOI:10.6084/m9.figshare.c.8112443
摘要

Polarization singularities have attracted considerable interest in photonic crystals (PhCs) due to their high quality-factor and selective response to circularly polarized light. In this work, we propose a strategy to manipulate the evolution of polarization singularities within degenerate bands in the magneto-optical PhC slab, by breaking geometric symmetry through unit structures and time-reversal symmetry through magnetic field. For C6 symmetry, the magnetic field lifts the degeneracy of bound states in the continuum (BICs), resulting in chiral BICs with opposite chirality. Reducing the symmetry to C3, an at-Γ parabolic point and six off-Γ circularly polarized singularity points (C-points) are observed. Applying the magnetic field, the parabolic point splits into four new C-points that subsequently undergo pairwise merging and annihilation with the pre-existing ones as the field strength increases, illustrating rich topological dynamics. Upon reduction to C2 symmetry, an at-Γ BIC and two off-Γ Dirac points are observed. Under the external magnetic field, the Dirac points evolve into two couples of C-points, where the surrounding highly circularly polarized states are simultaneously controlled by the field strength. In addition, flexible and on-demand modulation of the polarization singularities can be achieved by rotating the unit structure to break mirror symmetry and changing the magnetic field. Our work establishes the tuning approach of polarization singularities based on multiple symmetry-breaking, which enables effective chiroptical manipulation.

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